CN221074245U - Mechanical ore collecting and transferring device suitable for suspension mining vehicle - Google Patents

Abstract

The utility model relates to the technical field of deep sea ore collection, in particular to a mechanical ore collection and transportation device suitable for a suspension mining vehicle, which comprises a collecting device, a breaking device and a processing device, wherein the breaking device is arranged at the front end of the collecting device; the collecting device comprises a collecting pump, a collecting pump feed inlet and a collecting pump discharge outlet; and the channel device is arranged between the processing device and the feed inlet of the collecting pump. Aiming at the problem of overlarge pushing force during mechanical ore collection of a suspension mining vehicle, the utility model utilizes the rotating circumferential force to accelerate the collection of minerals by arranging the rotating device, and the utility model is arranged on the mining vehicle, thereby reducing the requirement on the pushing force during ore collection of the mining vehicle and improving the ore collection efficiency.

Description

Mechanical ore collecting and transferring device suitable for suspension mining vehicle

Technical Field

The utility model relates to the technical field of deep sea ore collection, in particular to a mechanical ore collection and transportation device suitable for a suspension mining vehicle.

Background

In the vast amount of deep sea, huge manganese nodule, cobalt crust, polymetallic sulfide ore resources are reserved. The existing ore collecting mode mostly adopts a crawler belt submerged mining car, and is driven by the huge thrust of the crawler belt to further finish ore collecting operation, but a large amount of plume can be generated.

In recent years, more environment-friendly suspension mining technology appears, but the suspension mining technology simultaneously faces the serious problems that the ore collection system cannot be provided with huge propelling force like a submerged crawler mining car during ore collection, so that the ore collection efficiency is low, and even the ore collection is stopped and the mining car is overturned.

Disclosure of utility model

The utility model aims to solve the defects in the prior art, and aims to solve the problems that the driving force is too large when the mechanical ore collection of a suspension mining vehicle is carried out, the driving force causes the increase of the power of a driving device of the suspension mining vehicle, the volume of the whole vehicle is increased, the layout of a ship body is difficult, and the like, and the power is increased to cause the problem of energy consumption, while the utility model provides the mechanical ore collection and transportation device suitable for the suspension mining vehicle, which improves the mining energy consumption ratio and comprises the following components:

The device comprises a collecting device, a soil breaking device and a processing device, wherein the soil breaking device is arranged at the front end of the collecting device and is connected with the processing device;

the collecting device comprises a collecting pump, a collecting pump feed inlet and a collecting pump discharge outlet;

And the channel device is arranged between the processing device and the feed inlet of the collecting pump.

Further, the collection device comprises a processing device, a frame, a sliding shoe and a storage bin, and the processing device comprises a transfer bin, a driving device and a rotating device.

Further, the soil breaking device is in a zigzag shape, and the soil breaking device is in contact with a material inlet of the transferring bin.

Further, the driving device is fixedly connected with the frame and arranged above the transferring bin.

Further, the driving device is connected with a rotating device for circumferential conveying.

Further, a storage bin feed inlet is formed between the storage bin and the transfer bin, the storage bin is connected with the bottom of the frame, and the rotating device is near the storage bin feed inlet.

Further, the transfer bin is obliquely arranged on the storage bin.

Further, the storage bin feed inlet is larger than the storage bin discharge outlet.

Further, the frame is connected with the sliding shoes through supporting devices, the supporting devices are matched with the sliding shoes, the supporting devices are symmetrically arranged on two sides of the frame, displacement sensors are arranged in the sliding shoes, and the sliding shoes are in contact with the ground.

Further, one end of the channel device is connected with a storage bin discharge hole formed in the storage bin, and the other end of the channel device is connected with a collecting pump feed inlet.

Compared with the prior art, the utility model has the beneficial effects that:

1) The utility model is arranged on the mining vehicle, can reduce the requirement on propulsion force when the mining vehicle collects the mine, improve the mine collection efficiency, reduce the energy consumption of the mining vehicle and improve the mining energy consumption ratio.

2) According to the utility model, the rotation device is arranged to accelerate the collection of minerals by utilizing the circumferential force of rotation.

Drawings

Various other advantages and benefits will become apparent to those of ordinary skill in the art upon reading the following detailed description of the preferred embodiments. The drawings are only for the purpose of illustrating preferred embodiments and are not to be construed as limiting the utility model.

FIG. 1 is a side view of the overall construction of a mechanical mine collection transfer apparatus adapted for use with a suspended mining vehicle in accordance with the present utility model;

FIG. 2 is a top view of the overall structure of a mechanical mine collection transfer apparatus adapted for use with a suspended mining vehicle in accordance with the present utility model;

FIG. 3 is a schematic view of a combination of a transfer bin and a storage bin of a mechanical mine collection transfer device adapted for use with a suspended mining vehicle in accordance with the present utility model;

FIG. 4 is a schematic view of a storage bin feed inlet of a mechanical mine collection transfer apparatus adapted for use with a suspended mining vehicle according to the present utility model;

Fig. 5 is a structural view of a turning device of a mechanical ore collecting and transporting device for a suspension mining vehicle according to the present utility model, wherein (a) is a general structural view of the turning device, and (b) is a plan view of the turning device.

Reference numerals

1: A collection device;

11: a breaking device; 12: a processing device;

121: a transfer bin; 122: a frame; 123: a slipper; 124: a driving device; 125: a rotating device; 126: a storage bin;

1211: a feed inlet of the transfer bin; 1221: a support device; 1261: a storage bin feed inlet; 1262: a storage bin discharge port;

2: a collecting device;

21: a collection pump; 22: collecting a feed inlet of a pump; 23: a discharge hole of the collecting pump;

3: a channel device;

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model. It will be apparent that the described embodiments are some, but not all, embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As used herein, the singular forms "a", "an", and "the" are intended to include the plural forms as well, unless expressly stated otherwise, as understood by those skilled in the art. It will be further understood that the terms "comprises" and/or "comprising," when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

Examples

Referring to fig. 1 and 2, a mechanical ore collecting and transporting device for a suspended mining vehicle according to this embodiment includes:

The device comprises an acquisition device 1, a soil breaking device 11 and a processing device 12, wherein the soil breaking device 11 is arranged at the front end of the acquisition device 1, and specifically, in the embodiment, the soil breaking device 11 is used for breaking the seabed mineral ground;

The collecting device 2 comprises a collecting pump 21, a collecting pump feeding hole 22 and a collecting pump discharging hole 23, specifically, in the embodiment, the collecting pump 21 is arranged at the rear end of the ore collecting and transporting device, and minerals in the storage bin 126 can be transported into the suspended mining vehicle relay bin by utilizing the hydraulic principle, so as to be lifted to an upper transport ship;

and a channel device 3, wherein the channel device 3 is arranged between the processing device 12 and the feed inlet 22 of the collecting pump.

Further, the collecting device 1 comprises a processing device 12, a frame 122, a sliding shoe 123 and a storage bin 126, wherein the processing device comprises a transferring bin 121, a driving device 124 and a rotating device 125, specifically, in the embodiment, the transferring bin 121 gathers minerals, the rotating device 125 is convenient to unfold and transfer, the frame 122 provides strength support for the whole fixing device, in addition, the frame 122 can serve as a supporting point to facilitate the fixation of the suspension mining vehicle, the driving device 124 is a hydraulic motor, and the rotating device 125 is powered.

Further, the breaking device 11 is serrated, and the breaking device 11 is in contact with the transfer bin feed inlet 1211 of the transfer bin 121, specifically, in this embodiment, after the breaking device 11 enters the ground to start working, minerals are collected at the transfer bin feed inlet 1211, where the breaking device 11 may have the following configuration scheme: the first configuration scheme is that the front end of the soil breaking device 11 is in a sawtooth shape, the rear end of the soil breaking device is in a smooth shape, and the smooth shape is contacted with the feed inlet 1211 of the transfer bin; the second configuration is that the whole of the soil breaking device 11 is saw-toothed and contacts with the feed opening 1211 of the transfer bin. In this embodiment, the second configuration scheme is adopted, and other schemes may be used for configuration in other embodiments.

Further, the driving device 124 is fixedly connected with the frame 122 and disposed above the transferring bin 121.

Further, the driving device 124 is connected to the rotating device 125 for circumferential conveying, specifically, in this embodiment, the rotating device 125 is designed as an arc turntable, and in other embodiments, other shapes such as a rectangle may be used for circumferential conveying of the ore, which is not limited in this embodiment.

Referring to fig. 3 and 4, a storage bin feeding hole 1261 is formed between the storage bin 126 and the transfer bin 121, the storage bin 126 is connected with the bottom of the frame 122, and the rotating device 125 is near the storage bin feeding hole 1261, specifically, in this embodiment, the shape of the storage bin feeding hole 1261 is circular, the shape of the storage bin feeding hole 1261 is not limited, and other shapes may be used in other embodiments, where the rotating device 125 and the storage bin feeding hole 1261 may have the following configurations: the first configuration is to provide a storage bin feed port 1261, and a rotating device 125 is provided near the storage bin feed port 1261; the second configuration is to provide a storage bin feed port 1261, and two rotating devices 125 are provided near the storage bin feed port; the third configuration scheme is that a storage bin feed port 1261 is arranged, and three rotating devices are arranged near the storage bin feed port; the fourth configuration scheme is that two storage bin feed inlets 1261 are arranged, and a rotating device is arranged near the storage bin feed inlets 1261; the fifth configuration scheme is that two storage bin feed inlets 1261 are arranged, and two rotating devices are arranged near the storage bin feed inlets 1261; a sixth configuration is to provide two magazine feed openings 1261 and three rotating devices near the magazine feed openings 1261. In this embodiment, the second configuration scheme is adopted, and other schemes may be used for configuration in other embodiments.

Further, the transfer bin 121 is disposed obliquely to the storage bin 126.

Further, the bin feed port 1261 is larger than the bin discharge port 1262, specifically, in this embodiment, the bin feed port 1261 is larger, facilitating entry of ore.

Further, the frame 122 is connected to the skid shoes 123 through the supporting device 1221, the supporting device 1221 is symmetrically arranged on two sides of the frame 122, the supporting device 1221 is matched with the skid shoes 123, the inside of the skid shoes 123 is provided with a displacement sensor, and the skid shoes 123 are contacted with the ground, specifically, in this embodiment, the supporting device 1221 is a T-shaped bracket, the skid shoes 123 are used as ground supporting points, and provides ground supporting points for mining of the suspended mining vehicle, the displacement sensor can feed back the earth breaking device 1 to the earth entering displacement, wherein the supporting device 1221 may have the following configuration scheme: the first configuration scheme is that two sides of the frame 122 are respectively provided with a supporting device 1221; the second configuration scheme is that two supporting devices 1221 are respectively arranged at two sides of the frame 122; the third configuration scheme is that three supporting devices 1221 are respectively arranged at two sides of the frame 122; the fourth configuration is to provide four supporting devices 1224 on both sides of the frame 122. In this embodiment, the second configuration scheme is adopted, and other schemes may be used for configuration in other embodiments.

More preferably, the computer receives the data fed back by the displacement sensor, judges whether the soil breaking device 11 reaches a set value according to the fed back data, if the soil breaking device 11 does not reach the set value, the operation end controls the soil breaking device 11 to continue to enter the soil, and if the soil breaking device 11 reaches the set value, the suspended mining vehicle can push the ore collecting and transporting device to transversely run for carrying out the operation, wherein the fed back data are height data in the embodiment.

Further, one end of the channel device 3 is connected with a storage bin discharge hole 1262 formed in the storage bin 126, and the other end of the channel device 3 is connected with the collecting pump feed hole 22.

In the actual use process, the suspended mining vehicle drives the operation of the ore collecting and transporting device, when the collecting pump 21 and the driving device 124 start to operate, seawater firstly enters the ore collecting and transporting device, the earth breaking device 11 contacts the ground, then the sliding shoe 123 is used as a fulcrum to be in shallow contact with the seabed ground under the action of the suspended mining vehicle, the earth entering depth of the earth breaking device 11 is controlled by judging the suspended mining vehicle according to the data transmitted by the judging displacement sensor, minerals and soil also start to gather at the feed inlet 1211 of the transporting bin when the ore collecting and transporting device advances, then the rotating device 125 starts to rotate under the driving of the driving device 124, namely a hydraulic motor, the rotating device 125 is designed into an arc turntable mode, the materials gathered and piled materials can be continuously driven to rotate, when the materials pass through the feed inlet 1261 of the storing bin, the materials are settled in the storing bin 126 under the action of gravity, and after the materials in the storing bin 126 enter the collecting device 2 through the channel device 3 according to the action of the hydraulic principle, the materials in the storing bin 126 are finally transported to the transporting ship through the collecting pump discharge port 23.

The above description is only a preferred embodiment of the present utility model, and the protection scope of the present utility model is not limited to the above examples, and all technical solutions belonging to the concept of the present utility model belong to the protection scope of the present utility model. It should be noted that modifications and adaptations to the present utility model may occur to one skilled in the art without departing from the principles of the present utility model and are intended to be within the scope of the present utility model.

Claims (5)

1. A mechanical mine collection transfer device for a suspended mining vehicle, comprising:

The device comprises a collecting device, a soil breaking device and a processing device, wherein the soil breaking device is arranged at the front end of the collecting device and is connected with the processing device;

the collecting device comprises a collecting pump, a collecting pump feed inlet and a collecting pump discharge outlet;

The channel device is arranged between the processing device and the feed inlet of the collecting pump;

The collecting device comprises a processing device, a rack, a sliding shoe and a storage bin, wherein the processing device comprises a transfer bin, a driving device and a rotating device;

wherein the soil breaking device is contacted with a transfer bin feed inlet of the transfer bin;

Wherein the driving device is fixedly connected with the frame and arranged above the transferring bin;

wherein the driving device is connected with a rotating device for circumferential conveying;

A storage bin feeding hole is formed between the storage bin and the transfer bin, the storage bin is connected with the bottom of the frame, and the rotating device is near the storage bin feeding hole;

The sliding shoes are characterized in that the machine frame is connected with the sliding shoes through supporting devices, the supporting devices are symmetrically arranged on two sides of the machine frame, the supporting devices are matched with the sliding shoes, displacement sensors are arranged in the sliding shoes, and the sliding shoes are in contact with the ground.

2. A mechanical mine collection and transfer device for a suspended mining vehicle according to claim 1, wherein the breaking means is saw-tooth-like.

3. A mechanical mineral aggregate transfer device for a suspended mining vehicle according to claim 1, characterized in that the transfer bin is arranged obliquely to the storage bin.

4. A mechanical mineral aggregate transfer device for a suspended mining vehicle according to claim 1, characterized in that the storage bin feed opening is larger than the storage bin discharge opening.

5. A mechanical mineral collecting and transporting device for a suspended mining vehicle according to claim 1, characterized in that one end of the channel means is connected to a discharge opening of a storage bin provided in the storage bin, and the other end of the channel means is connected to a feed opening of the collecting pump.